src/interpreter/interpreter.cc - v8/v8.git - Git at Google

 // Copyright 2015 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "src/interpreter/interpreter.h"

 #include <fstream>
 #include <memory>

 #include "builtins-generated/bytecodes-builtins-list.h"
 #include "src/ast/prettyprinter.h"
 #include "src/ast/scopes.h"
 #include "src/codegen/compiler.h"
 #include "src/codegen/unoptimized-compilation-info.h"
 #include "src/init/bootstrapper.h"
 #include "src/init/setup-isolate.h"
 #include "src/interpreter/bytecode-generator.h"
 #include "src/interpreter/bytecodes.h"
 #include "src/logging/counters-inl.h"
 #include "src/objects/objects-inl.h"
 #include "src/objects/shared-function-info.h"
 #include "src/objects/slots.h"
 #include "src/objects/visitors.h"
 #include "src/parsing/parse-info.h"
 #include "src/snapshot/snapshot.h"
 #include "src/utils/ostreams.h"

 namespace v8 {
 namespace internal {
 namespace interpreter {

 class InterpreterCompilationJob final : public UnoptimizedCompilationJob {
  public:
   InterpreterCompilationJob(
       ParseInfo* parse_info, FunctionLiteral* literal,
       AccountingAllocator* allocator,
       std::vector<FunctionLiteral*>* eager_inner_literals);

  protected:
   Status ExecuteJobImpl() final;
   Status FinalizeJobImpl(Handle<SharedFunctionInfo> shared_info,
                          Isolate* isolate) final;

  private:
   BytecodeGenerator* generator() { return &generator_; }
   void CheckAndPrintBytecodeMismatch(Isolate* isolate, Handle<Script> script,
                                      Handle<BytecodeArray> bytecode);

   Zone zone_;
   UnoptimizedCompilationInfo compilation_info_;
   BytecodeGenerator generator_;

   DISALLOW_COPY_AND_ASSIGN(InterpreterCompilationJob);
 };

 Interpreter::Interpreter(Isolate* isolate)
     : isolate_(isolate),
       interpreter_entry_trampoline_instruction_start_(kNullAddress) {
   memset(dispatch_table_, 0, sizeof(dispatch_table_));

   if (FLAG_trace_ignition_dispatches) {
     static const int kBytecodeCount = static_cast<int>(Bytecode::kLast) + 1;
     bytecode_dispatch_counters_table_.reset(
         new uintptr_t[kBytecodeCount * kBytecodeCount]);
     memset(bytecode_dispatch_counters_table_.get(), 0,
            sizeof(uintptr_t) * kBytecodeCount * kBytecodeCount);
   }
 }

 namespace {

 int BuiltinIndexFromBytecode(Bytecode bytecode, OperandScale operand_scale) {
   int index = BytecodeOperands::OperandScaleAsIndex(operand_scale) *
                   kNumberOfBytecodeHandlers +
               static_cast<int>(bytecode);
   int offset = kBytecodeToBuiltinsMapping[index];
   return offset >= 0 ? Builtins::kFirstBytecodeHandler + offset
                      : Builtins::kIllegalHandler;
 }

 }  // namespace

 Code Interpreter::GetBytecodeHandler(Bytecode bytecode,
                                      OperandScale operand_scale) {
   int builtin_index = BuiltinIndexFromBytecode(bytecode, operand_scale);
   Builtins* builtins = isolate_->builtins();
   return builtins->builtin(builtin_index);
 }

 void Interpreter::SetBytecodeHandler(Bytecode bytecode,
                                      OperandScale operand_scale, Code handler) {
   DCHECK(handler.is_off_heap_trampoline());
   DCHECK(handler.kind() == Code::BYTECODE_HANDLER);
   size_t index = GetDispatchTableIndex(bytecode, operand_scale);
   dispatch_table_[index] = handler.InstructionStart();
 }

 // static
 size_t Interpreter::GetDispatchTableIndex(Bytecode bytecode,
                                           OperandScale operand_scale) {
   static const size_t kEntriesPerOperandScale = 1u << kBitsPerByte;
   size_t index = static_cast<size_t>(bytecode);
   return index + BytecodeOperands::OperandScaleAsIndex(operand_scale) *
                      kEntriesPerOperandScale;
 }

 int Interpreter::InterruptBudget() {
   return FLAG_interrupt_budget;
 }

 namespace {

 void MaybePrintAst(ParseInfo* parse_info,
                    UnoptimizedCompilationInfo* compilation_info) {
   if (!FLAG_print_ast) return;

   StdoutStream os;
   std::unique_ptr<char[]> name = compilation_info->literal()->GetDebugName();
   os << "[generating bytecode for function: " << name.get() << "]" << std::endl;
 #ifdef DEBUG
   os << "--- AST ---" << std::endl
      << AstPrinter(parse_info->stack_limit())
             .PrintProgram(compilation_info->literal())
      << std::endl;
 #endif  // DEBUG
 }

 bool ShouldPrintBytecode(Handle<SharedFunctionInfo> shared) {
   if (!FLAG_print_bytecode) return false;

   // Checks whether function passed the filter.
   if (shared->is_toplevel()) {
     Vector<const char> filter = CStrVector(FLAG_print_bytecode_filter);
     return (filter.length() == 0) || (filter.length() == 1 && filter[0] == '*');
   } else {
     return shared->PassesFilter(FLAG_print_bytecode_filter);
   }
 }

 }  // namespace

 InterpreterCompilationJob::InterpreterCompilationJob(
     ParseInfo* parse_info, FunctionLiteral* literal,
     AccountingAllocator* allocator,
     std::vector<FunctionLiteral*>* eager_inner_literals)
     : UnoptimizedCompilationJob(parse_info->stack_limit(), parse_info,
                                 &compilation_info_),
       zone_(allocator, ZONE_NAME),
       compilation_info_(&zone_, parse_info, literal),
       generator_(&compilation_info_, parse_info->ast_string_constants(),
                  eager_inner_literals) {}

 InterpreterCompilationJob::Status InterpreterCompilationJob::ExecuteJobImpl() {
   RuntimeCallTimerScope runtimeTimerScope(
       parse_info()->runtime_call_stats(),
       RuntimeCallCounterId::kCompileIgnition,
       RuntimeCallStats::kThreadSpecific);
   // TODO(lpy): add support for background compilation RCS trace.
   TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("v8.compile"), "V8.CompileIgnition");

   // Print AST if flag is enabled. Note, if compiling on a background thread
   // then ASTs from different functions may be intersperse when printed.
   MaybePrintAst(parse_info(), compilation_info());

   generator()->GenerateBytecode(stack_limit());

   if (generator()->HasStackOverflow()) {
     return FAILED;
   }
   return SUCCEEDED;
 }

 #ifdef DEBUG
 void InterpreterCompilationJob::CheckAndPrintBytecodeMismatch(
     Isolate* isolate, Handle<Script> script, Handle<BytecodeArray> bytecode) {
   int first_mismatch = generator()->CheckBytecodeMatches(*bytecode);
   if (first_mismatch >= 0) {
     parse_info()->ast_value_factory()->Internalize(isolate);
     DeclarationScope::AllocateScopeInfos(parse_info(), isolate);

     Handle<BytecodeArray> new_bytecode =
         generator()->FinalizeBytecode(isolate, script);

     std::cerr << "Bytecode mismatch";
 #ifdef OBJECT_PRINT
     std::cerr << " found for function: ";
     Handle<String> name = parse_info()->function_name()->string();
     if (name->length() == 0) {
       std::cerr << "anonymous";
     } else {
       name->StringPrint(std::cerr);
     }
     Object script_name = script->GetNameOrSourceURL();
     if (script_name.IsString()) {
       std::cerr << " ";
       String::cast(script_name).StringPrint(std::cerr);
       std::cerr << ":" << parse_info()->start_position();
     }
 #endif
     std::cerr << "\nOriginal bytecode:\n";
     bytecode->Disassemble(std::cerr);
     std::cerr << "\nNew bytecode:\n";
     new_bytecode->Disassemble(std::cerr);
     FATAL("Bytecode mismatch at offset %d\n", first_mismatch);
   }
 }
 #endif

 InterpreterCompilationJob::Status InterpreterCompilationJob::FinalizeJobImpl(
     Handle<SharedFunctionInfo> shared_info, Isolate* isolate) {
   RuntimeCallTimerScope runtimeTimerScope(
       parse_info()->runtime_call_stats(),
       RuntimeCallCounterId::kCompileIgnitionFinalization);
   TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("v8.compile"),
                "V8.CompileIgnitionFinalization");

   Handle<BytecodeArray> bytecodes = compilation_info_.bytecode_array<Isolate>();
   if (bytecodes.is_null()) {
     bytecodes = generator()->FinalizeBytecode(
         isolate, handle(Script::cast(shared_info->script()), isolate));
     if (generator()->HasStackOverflow()) {
       return FAILED;
     }
     compilation_info()->SetBytecodeArray(bytecodes);
   }

   if (compilation_info()->SourcePositionRecordingMode() ==
       SourcePositionTableBuilder::RecordingMode::RECORD_SOURCE_POSITIONS) {
     Handle<ByteArray> source_position_table =
         generator()->FinalizeSourcePositionTable(isolate);
     bytecodes->set_source_position_table(*source_position_table);
   }

   if (ShouldPrintBytecode(shared_info)) {
     StdoutStream os;
     std::unique_ptr<char[]> name =
         compilation_info()->literal()->GetDebugName();
     os << "[generated bytecode for function: " << name.get() << " ("
        << shared_info << ")]" << std::endl;
     bytecodes->Disassemble(os);
     os << std::flush;
   }

 #ifdef DEBUG
   CheckAndPrintBytecodeMismatch(
       isolate, handle(Script::cast(shared_info->script()), isolate), bytecodes);
 #endif

   return SUCCEEDED;
 }

 std::unique_ptr<UnoptimizedCompilationJob> Interpreter::NewCompilationJob(
     ParseInfo* parse_info, FunctionLiteral* literal,
     AccountingAllocator* allocator,
     std::vector<FunctionLiteral*>* eager_inner_literals) {
   return std::make_unique<InterpreterCompilationJob>(
       parse_info, literal, allocator, eager_inner_literals);
 }

 std::unique_ptr<UnoptimizedCompilationJob>
 Interpreter::NewSourcePositionCollectionJob(
     ParseInfo* parse_info, FunctionLiteral* literal,
     Handle<BytecodeArray> existing_bytecode, AccountingAllocator* allocator) {
   auto job = std::make_unique<InterpreterCompilationJob>(parse_info, literal,
                                                          allocator, nullptr);
   job->compilation_info()->SetBytecodeArray(existing_bytecode);
   return job;
 }

 void Interpreter::ForEachBytecode(
     const std::function<void(Bytecode, OperandScale)>& f) {
   constexpr OperandScale kOperandScales[] = {
 #define VALUE(Name, _) OperandScale::k##Name,
       OPERAND_SCALE_LIST(VALUE)
 #undef VALUE
   };

   for (OperandScale operand_scale : kOperandScales) {
     for (int i = 0; i < Bytecodes::kBytecodeCount; i++) {
       f(Bytecodes::FromByte(i), operand_scale);
     }
   }
 }

 void Interpreter::Initialize() {
   Builtins* builtins = isolate_->builtins();

   // Set the interpreter entry trampoline entry point now that builtins are
   // initialized.
   Handle<Code> code = BUILTIN_CODE(isolate_, InterpreterEntryTrampoline);
   DCHECK(builtins->is_initialized());
   DCHECK(code->is_off_heap_trampoline() ||
          isolate_->heap()->IsImmovable(*code));
   interpreter_entry_trampoline_instruction_start_ = code->InstructionStart();

   // Initialize the dispatch table.
   Code illegal = builtins->builtin(Builtins::kIllegalHandler);
   int builtin_id = Builtins::kFirstBytecodeHandler;
   ForEachBytecode([=, &builtin_id](Bytecode bytecode,
                                    OperandScale operand_scale) {
     Code handler = illegal;
     if (Bytecodes::BytecodeHasHandler(bytecode, operand_scale)) {
 #ifdef DEBUG
       std::string builtin_name(Builtins::name(builtin_id));
       std::string expected_name =
           Bytecodes::ToString(bytecode, operand_scale, "") + "Handler";
       DCHECK_EQ(expected_name, builtin_name);
 #endif
       handler = builtins->builtin(builtin_id++);
     }
     SetBytecodeHandler(bytecode, operand_scale, handler);
   });
   DCHECK(builtin_id == Builtins::builtin_count);
   DCHECK(IsDispatchTableInitialized());
 }

 bool Interpreter::IsDispatchTableInitialized() const {
   return dispatch_table_[0] != kNullAddress;
 }

 const char* Interpreter::LookupNameOfBytecodeHandler(const Code code) {
   if (code.kind() == Code::BYTECODE_HANDLER) {
     return Builtins::name(code.builtin_index());
   }
   return nullptr;
 }

 uintptr_t Interpreter::GetDispatchCounter(Bytecode from, Bytecode to) const {
   int from_index = Bytecodes::ToByte(from);
   int to_index = Bytecodes::ToByte(to);
   return bytecode_dispatch_counters_table_[from_index * kNumberOfBytecodes +
                                            to_index];
 }

 Local<v8::Object> Interpreter::GetDispatchCountersObject() {
   v8::Isolate* isolate = reinterpret_cast<v8::Isolate*>(isolate_);
   Local<v8::Context> context = isolate->GetCurrentContext();

   Local<v8::Object> counters_map = v8::Object::New(isolate);

   // Output is a JSON-encoded object of objects.
   //
   // The keys on the top level object are source bytecodes,
   // and corresponding value are objects. Keys on these last are the
   // destinations of the dispatch and the value associated is a counter for
   // the correspondent source-destination dispatch chain.
   //
   // Only non-zero counters are written to file, but an entry in the top-level
   // object is always present, even if the value is empty because all counters
   // for that source are zero.

   for (int from_index = 0; from_index < kNumberOfBytecodes; ++from_index) {
     Bytecode from_bytecode = Bytecodes::FromByte(from_index);
     Local<v8::Object> counters_row = v8::Object::New(isolate);

     for (int to_index = 0; to_index < kNumberOfBytecodes; ++to_index) {
       Bytecode to_bytecode = Bytecodes::FromByte(to_index);
       uintptr_t counter = GetDispatchCounter(from_bytecode, to_bytecode);

       if (counter > 0) {
         std::string to_name = Bytecodes::ToString(to_bytecode);
         Local<v8::String> to_name_object =
             v8::String::NewFromUtf8(isolate, to_name.c_str(),
                                     NewStringType::kNormal)
                 .ToLocalChecked();
         Local<v8::Number> counter_object = v8::Number::New(isolate, counter);
         CHECK(counters_row
                   ->DefineOwnProperty(context, to_name_object, counter_object)
                   .IsJust());
       }
     }

     std::string from_name = Bytecodes::ToString(from_bytecode);
     Local<v8::String> from_name_object =
         v8::String::NewFromUtf8(isolate, from_name.c_str(),
                                 NewStringType::kNormal)
             .ToLocalChecked();

     CHECK(
         counters_map->DefineOwnProperty(context, from_name_object, counters_row)
             .IsJust());
   }

   return counters_map;
 }

 }  // namespace interpreter
 }  // namespace internal
 }  // namespace v8
	// Copyright 2015 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "src/interpreter/interpreter.h"

	#include <fstream>
	#include <memory>

	#include "builtins-generated/bytecodes-builtins-list.h"
	#include "src/ast/prettyprinter.h"
	#include "src/ast/scopes.h"
	#include "src/codegen/compiler.h"
	#include "src/codegen/unoptimized-compilation-info.h"
	#include "src/init/bootstrapper.h"
	#include "src/init/setup-isolate.h"
	#include "src/interpreter/bytecode-generator.h"
	#include "src/interpreter/bytecodes.h"
	#include "src/logging/counters-inl.h"
	#include "src/objects/objects-inl.h"
	#include "src/objects/shared-function-info.h"
	#include "src/objects/slots.h"
	#include "src/objects/visitors.h"
	#include "src/parsing/parse-info.h"
	#include "src/snapshot/snapshot.h"
	#include "src/utils/ostreams.h"

	namespace v8 {
	namespace internal {
	namespace interpreter {

	class InterpreterCompilationJob final : public UnoptimizedCompilationJob {
	public:
	InterpreterCompilationJob(
	ParseInfo* parse_info, FunctionLiteral* literal,
	AccountingAllocator* allocator,
	std::vector<FunctionLiteral> eager_inner_literals);

	protected:
	Status ExecuteJobImpl() final;
	Status FinalizeJobImpl(Handle<SharedFunctionInfo> shared_info,
	Isolate* isolate) final;

	private:
	BytecodeGenerator* generator() { return &generator_; }
	void CheckAndPrintBytecodeMismatch(Isolate* isolate, Handle<Script> script,
	Handle<BytecodeArray> bytecode);

	Zone zone_;
	UnoptimizedCompilationInfo compilation_info_;
	BytecodeGenerator generator_;

	DISALLOW_COPY_AND_ASSIGN(InterpreterCompilationJob);
	};

	Interpreter::Interpreter(Isolate* isolate)
	: isolate_(isolate),
	interpreter_entry_trampoline_instruction_start_(kNullAddress) {
	memset(dispatch_table_, 0, sizeof(dispatch_table_));

	if (FLAG_trace_ignition_dispatches) {
	static const int kBytecodeCount = static_cast<int>(Bytecode::kLast) + 1;
	bytecode_dispatch_counters_table_.reset(
	new uintptr_t[kBytecodeCount * kBytecodeCount]);
	memset(bytecode_dispatch_counters_table_.get(), 0,
	sizeof(uintptr_t) * kBytecodeCount * kBytecodeCount);
	}
	}

	namespace {

	int BuiltinIndexFromBytecode(Bytecode bytecode, OperandScale operand_scale) {
	int index = BytecodeOperands::OperandScaleAsIndex(operand_scale) *
	kNumberOfBytecodeHandlers +
	static_cast<int>(bytecode);
	int offset = kBytecodeToBuiltinsMapping[index];
	return offset >= 0 ? Builtins::kFirstBytecodeHandler + offset
	: Builtins::kIllegalHandler;
	}

	} // namespace

	Code Interpreter::GetBytecodeHandler(Bytecode bytecode,
	OperandScale operand_scale) {
	int builtin_index = BuiltinIndexFromBytecode(bytecode, operand_scale);
	Builtins* builtins = isolate_->builtins();
	return builtins->builtin(builtin_index);
	}

	void Interpreter::SetBytecodeHandler(Bytecode bytecode,
	OperandScale operand_scale, Code handler) {
	DCHECK(handler.is_off_heap_trampoline());
	DCHECK(handler.kind() == Code::BYTECODE_HANDLER);
	size_t index = GetDispatchTableIndex(bytecode, operand_scale);
	dispatch_table_[index] = handler.InstructionStart();
	}

	// static
	size_t Interpreter::GetDispatchTableIndex(Bytecode bytecode,
	OperandScale operand_scale) {
	static const size_t kEntriesPerOperandScale = 1u << kBitsPerByte;
	size_t index = static_cast<size_t>(bytecode);
	return index + BytecodeOperands::OperandScaleAsIndex(operand_scale) *
	kEntriesPerOperandScale;
	}

	int Interpreter::InterruptBudget() {
	return FLAG_interrupt_budget;
	}

	namespace {

	void MaybePrintAst(ParseInfo* parse_info,
	UnoptimizedCompilationInfo* compilation_info) {
	if (!FLAG_print_ast) return;

	StdoutStream os;
	std::unique_ptr<char[]> name = compilation_info->literal()->GetDebugName();
	os << "[generating bytecode for function: " << name.get() << "]" << std::endl;
	#ifdef DEBUG
	os << "--- AST ---" << std::endl
	<< AstPrinter(parse_info->stack_limit())
	.PrintProgram(compilation_info->literal())
	<< std::endl;
	#endif // DEBUG
	}

	bool ShouldPrintBytecode(Handle<SharedFunctionInfo> shared) {
	if (!FLAG_print_bytecode) return false;

	// Checks whether function passed the filter.
	if (shared->is_toplevel()) {
	Vector<const char> filter = CStrVector(FLAG_print_bytecode_filter);
	return (filter.length() == 0) \|\| (filter.length() == 1 && filter[0] == '*');
	} else {
	return shared->PassesFilter(FLAG_print_bytecode_filter);
	}
	}

	} // namespace

	InterpreterCompilationJob::InterpreterCompilationJob(
	ParseInfo* parse_info, FunctionLiteral* literal,
	AccountingAllocator* allocator,
	std::vector<FunctionLiteral> eager_inner_literals)
	: UnoptimizedCompilationJob(parse_info->stack_limit(), parse_info,
	&compilation_info_),
	zone_(allocator, ZONE_NAME),
	compilation_info_(&zone_, parse_info, literal),
	generator_(&compilation_info_, parse_info->ast_string_constants(),
	eager_inner_literals) {}

	InterpreterCompilationJob::Status InterpreterCompilationJob::ExecuteJobImpl() {
	RuntimeCallTimerScope runtimeTimerScope(
	parse_info()->runtime_call_stats(),
	RuntimeCallCounterId::kCompileIgnition,
	RuntimeCallStats::kThreadSpecific);
	// TODO(lpy): add support for background compilation RCS trace.
	TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("v8.compile"), "V8.CompileIgnition");

	// Print AST if flag is enabled. Note, if compiling on a background thread
	// then ASTs from different functions may be intersperse when printed.
	MaybePrintAst(parse_info(), compilation_info());

	generator()->GenerateBytecode(stack_limit());

	if (generator()->HasStackOverflow()) {
	return FAILED;
	}
	return SUCCEEDED;
	}

	#ifdef DEBUG
	void InterpreterCompilationJob::CheckAndPrintBytecodeMismatch(
	Isolate* isolate, Handle<Script> script, Handle<BytecodeArray> bytecode) {
	int first_mismatch = generator()->CheckBytecodeMatches(*bytecode);
	if (first_mismatch >= 0) {
	parse_info()->ast_value_factory()->Internalize(isolate);
	DeclarationScope::AllocateScopeInfos(parse_info(), isolate);

	Handle<BytecodeArray> new_bytecode =
	generator()->FinalizeBytecode(isolate, script);

	std::cerr << "Bytecode mismatch";
	#ifdef OBJECT_PRINT
	std::cerr << " found for function: ";
	Handle<String> name = parse_info()->function_name()->string();
	if (name->length() == 0) {
	std::cerr << "anonymous";
	} else {
	name->StringPrint(std::cerr);
	}
	Object script_name = script->GetNameOrSourceURL();
	if (script_name.IsString()) {
	std::cerr << " ";
	String::cast(script_name).StringPrint(std::cerr);
	std::cerr << ":" << parse_info()->start_position();
	}
	#endif
	std::cerr << "\nOriginal bytecode:\n";
	bytecode->Disassemble(std::cerr);
	std::cerr << "\nNew bytecode:\n";
	new_bytecode->Disassemble(std::cerr);
	FATAL("Bytecode mismatch at offset %d\n", first_mismatch);
	}
	}
	#endif

	InterpreterCompilationJob::Status InterpreterCompilationJob::FinalizeJobImpl(
	Handle<SharedFunctionInfo> shared_info, Isolate* isolate) {
	RuntimeCallTimerScope runtimeTimerScope(
	parse_info()->runtime_call_stats(),
	RuntimeCallCounterId::kCompileIgnitionFinalization);
	TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("v8.compile"),
	"V8.CompileIgnitionFinalization");

	Handle<BytecodeArray> bytecodes = compilation_info_.bytecode_array<Isolate>();
	if (bytecodes.is_null()) {
	bytecodes = generator()->FinalizeBytecode(
	isolate, handle(Script::cast(shared_info->script()), isolate));
	if (generator()->HasStackOverflow()) {
	return FAILED;
	}
	compilation_info()->SetBytecodeArray(bytecodes);
	}

	if (compilation_info()->SourcePositionRecordingMode() ==
	SourcePositionTableBuilder::RecordingMode::RECORD_SOURCE_POSITIONS) {
	Handle<ByteArray> source_position_table =
	generator()->FinalizeSourcePositionTable(isolate);
	bytecodes->set_source_position_table(*source_position_table);
	}

	if (ShouldPrintBytecode(shared_info)) {
	StdoutStream os;
	std::unique_ptr<char[]> name =
	compilation_info()->literal()->GetDebugName();
	os << "[generated bytecode for function: " << name.get() << " ("
	<< shared_info << ")]" << std::endl;
	bytecodes->Disassemble(os);
	os << std::flush;
	}

	#ifdef DEBUG
	CheckAndPrintBytecodeMismatch(
	isolate, handle(Script::cast(shared_info->script()), isolate), bytecodes);
	#endif

	return SUCCEEDED;
	}

	std::unique_ptr<UnoptimizedCompilationJob> Interpreter::NewCompilationJob(
	ParseInfo* parse_info, FunctionLiteral* literal,
	AccountingAllocator* allocator,
	std::vector<FunctionLiteral> eager_inner_literals) {
	return std::make_unique<InterpreterCompilationJob>(
	parse_info, literal, allocator, eager_inner_literals);
	}

	std::unique_ptr<UnoptimizedCompilationJob>
	Interpreter::NewSourcePositionCollectionJob(
	ParseInfo* parse_info, FunctionLiteral* literal,
	Handle<BytecodeArray> existing_bytecode, AccountingAllocator* allocator) {
	auto job = std::make_unique<InterpreterCompilationJob>(parse_info, literal,
	allocator, nullptr);
	job->compilation_info()->SetBytecodeArray(existing_bytecode);
	return job;
	}

	void Interpreter::ForEachBytecode(
	const std::function<void(Bytecode, OperandScale)>& f) {
	constexpr OperandScale kOperandScales[] = {
	#define VALUE(Name, _) OperandScale::k##Name,
	OPERAND_SCALE_LIST(VALUE)
	#undef VALUE
	};

	for (OperandScale operand_scale : kOperandScales) {
	for (int i = 0; i < Bytecodes::kBytecodeCount; i++) {
	f(Bytecodes::FromByte(i), operand_scale);
	}
	}
	}

	void Interpreter::Initialize() {
	Builtins* builtins = isolate_->builtins();

	// Set the interpreter entry trampoline entry point now that builtins are
	// initialized.
	Handle<Code> code = BUILTIN_CODE(isolate_, InterpreterEntryTrampoline);
	DCHECK(builtins->is_initialized());
	DCHECK(code->is_off_heap_trampoline() \|\|
	isolate_->heap()->IsImmovable(*code));
	interpreter_entry_trampoline_instruction_start_ = code->InstructionStart();

	// Initialize the dispatch table.
	Code illegal = builtins->builtin(Builtins::kIllegalHandler);
	int builtin_id = Builtins::kFirstBytecodeHandler;
	ForEachBytecode([=, &builtin_id](Bytecode bytecode,
	OperandScale operand_scale) {
	Code handler = illegal;
	if (Bytecodes::BytecodeHasHandler(bytecode, operand_scale)) {
	#ifdef DEBUG
	std::string builtin_name(Builtins::name(builtin_id));
	std::string expected_name =
	Bytecodes::ToString(bytecode, operand_scale, "") + "Handler";
	DCHECK_EQ(expected_name, builtin_name);
	#endif
	handler = builtins->builtin(builtin_id++);
	}
	SetBytecodeHandler(bytecode, operand_scale, handler);
	});
	DCHECK(builtin_id == Builtins::builtin_count);
	DCHECK(IsDispatchTableInitialized());
	}

	bool Interpreter::IsDispatchTableInitialized() const {
	return dispatch_table_[0] != kNullAddress;
	}

	const char* Interpreter::LookupNameOfBytecodeHandler(const Code code) {
	if (code.kind() == Code::BYTECODE_HANDLER) {
	return Builtins::name(code.builtin_index());
	}
	return nullptr;
	}

	uintptr_t Interpreter::GetDispatchCounter(Bytecode from, Bytecode to) const {
	int from_index = Bytecodes::ToByte(from);
	int to_index = Bytecodes::ToByte(to);
	return bytecode_dispatch_counters_table_[from_index * kNumberOfBytecodes +
	to_index];
	}

	Local<v8::Object> Interpreter::GetDispatchCountersObject() {
	v8::Isolate* isolate = reinterpret_cast<v8::Isolate*>(isolate_);
	Local<v8::Context> context = isolate->GetCurrentContext();

	Local<v8::Object> counters_map = v8::Object::New(isolate);

	// Output is a JSON-encoded object of objects.
	//
	// The keys on the top level object are source bytecodes,
	// and corresponding value are objects. Keys on these last are the
	// destinations of the dispatch and the value associated is a counter for
	// the correspondent source-destination dispatch chain.
	//
	// Only non-zero counters are written to file, but an entry in the top-level
	// object is always present, even if the value is empty because all counters
	// for that source are zero.

	for (int from_index = 0; from_index < kNumberOfBytecodes; ++from_index) {
	Bytecode from_bytecode = Bytecodes::FromByte(from_index);
	Local<v8::Object> counters_row = v8::Object::New(isolate);

	for (int to_index = 0; to_index < kNumberOfBytecodes; ++to_index) {
	Bytecode to_bytecode = Bytecodes::FromByte(to_index);
	uintptr_t counter = GetDispatchCounter(from_bytecode, to_bytecode);

	if (counter > 0) {
	std::string to_name = Bytecodes::ToString(to_bytecode);
	Local<v8::String> to_name_object =
	v8::String::NewFromUtf8(isolate, to_name.c_str(),
	NewStringType::kNormal)
	.ToLocalChecked();
	Local<v8::Number> counter_object = v8::Number::New(isolate, counter);
	CHECK(counters_row
	->DefineOwnProperty(context, to_name_object, counter_object)
	.IsJust());
	}
	}

	std::string from_name = Bytecodes::ToString(from_bytecode);
	Local<v8::String> from_name_object =
	v8::String::NewFromUtf8(isolate, from_name.c_str(),
	NewStringType::kNormal)
	.ToLocalChecked();

	CHECK(
	counters_map->DefineOwnProperty(context, from_name_object, counters_row)
	.IsJust());
	}

	return counters_map;
	}

	} // namespace interpreter
	} // namespace internal
	} // namespace v8